Adaptive projector

ABSTRACT

An apparatus for processing data includes a projector, which is configured to project content onto at least a part of a scene. A processor is configured to detect a location of an eye of a person in the scene and to control the projector so as to reduce an intensity of the projected content in an area of the eye.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of PCT Patent ApplicationPCT/IB2011/053192, filed Jul. 18, 2011, which claims the benefit of U.S.Provisional Application No. 61/365,788, filed Jul. 20, 2010. Thisapplication is related to another U.S. patent application, filed on evendate, entitled “Interactive Reality Augmentation for NaturalInteraction”. All of these related applications are incorporated hereinby reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to natural interaction systems. Moreparticularly this invention relates to adaptive reality augmentation and3-dimensional input interfaces.

2. Description of the Related Art

Natural user interfaces are gaining momentum in the entertainment andcomputer industry. Gesture controls are supplementing or replacing moreconventional and less natural interfaces such as keyboard and mouse,game controller, and remote control. The user interactions, however,continue to relate largely to the computer monitor, thus limitingapplicability and ease of use of such interfaces. Some of the gesturecontrols rely on optical 3-dimensional mapping.

Various methods are known in the art for optical 3-D mapping, i.e.,generating a 3-dimensional profile of the surface of an object byprocessing an optical image of the object. This sort of profile is alsoreferred to as a depth map or depth image, and 3-D mapping is alsoreferred to as depth mapping.

Some methods are based on projecting a laser speckle pattern onto theobject, and then analyzing an image of the pattern on the object. Forexample, PCT International Publication WO 2007/043036, whose disclosureis incorporated herein by reference, describes a system and method forobject reconstruction in which a coherent light source and a generatorof a random speckle pattern project onto the object a coherent randomspeckle pattern. An imaging unit detects the light response of theilluminated region and generates image data. Shifts of the pattern inthe image of the object relative to a reference image of the pattern areused in real time reconstruction of a 3-D map of the object. Furthermethods for 3-D mapping using speckle patterns are described, forexample, in PCT International Publication WO 2007/105205, whosedisclosure is incorporated herein by reference.

SUMMARY

The present invention, in certain embodiments thereof seeks to providean improved content projection device, which is aware of objects in itsfield of view, recognizing such objects as suitable for projection ofcontent thereon. The projection device may adapt to the geometry andcharacter of the objects by controlling scale, distortion, focus of theprojected content, and varying the projected content itself.Additionally or alternatively, the projection device may adapt theprojected content according to the relationship of the viewer to theprojected content, such as its gaze vector, distance from the surfaceonto which content is projected, and other similar parameters. The 2D/3Dinput device used to analyze the geometry for projection can also beused to interact with the projected content.

According to disclosed embodiments of the invention, methods andapparatus are provided for the projection of content, such as the inputdevice interface, using a 3-dimensional input device as means ofdetermining the optimal objects to serve as substrate for such contentprojection.

There is provided according to embodiments of the invention an apparatusfor processing data, including a sensing element for acquiring a sceneincluding a 2-dimensional camera and a 3-dimensional camera, a processorlinked to the 3-dimensional camera and the 2-dimensional camera andprogrammed to produce a depth map of the scene using an output of the3-dimensional camera, and to coordinate the depth map with a2-dimensional image captured by the 2-dimensional camera to identify a3-dimensional object in the scene that meets predetermined criteria forprojection of images thereon, and a content projector for establishing aprojected image onto the 3-dimensional object responsively toinstructions of the processor.

According to an aspect of the apparatus, coordinating the depth mapincludes identifying a position of the 3-dimensional object with sixdegrees of freedom with respect to a reference system of coordinates,wherein the content projector is operative to compensate for scale,pitch, yaw and angular rotation of the 3-dimensional object.

According to a further aspect of the apparatus, coordinating the depthmap includes referencing a database of 3-dimensional object definitionsand comparing the 3-dimensional object with the definitions in thedatabase.

An aspect of the apparatus includes a wearable monitor, wherein thecontent projector is operative to establish the projected image as avirtual image in the wearable monitor or in a virtual space. The sensingelement, the processor and the content projector may be incorporated inthe wearable monitor.

According to a further aspect of the apparatus, the content projector isoperative to establish the projected image onto a virtual surface foruser interaction therewith.

According to yet another aspect of the apparatus, the processor isoperative for controlling a computer application responsively to agesture and wherein the projected image includes a user interface forcontrol of the computer application.

According to aspect of the apparatus, the projected image includeswritten content.

In another embodiment, an apparatus for processing data includes aprojector, which is configured to project content onto at least a partof a scene, and a processor, which is configured to detect a location ofan eye of a person in the scene and to control the projector so as toreduce an intensity of the projected content in an area of the eye.

Other embodiments of the invention provide methods for carrying out thefunction of the above-described apparatus.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

For a better understanding of the present invention, reference is madeto the detailed description of the invention, by way of example, whichis to be read in conjunction with the following drawings, wherein likeelements are given like reference numerals, and wherein:

FIG. 1 is a schematic pictorial illustration of an interactivethree-dimensional video display system, which is constructed andoperative in accordance with a disclosed embodiment of the invention;

FIG. 2 is a block diagram of the system shown in FIG. 1, which isconstructed and operative in accordance with an embodiment of theinvention;

FIG. 3 is a block diagram that shows functional elements of a portion ofan exemplary processing device, which is constructed and operative inaccordance with an embodiment of the invention;

FIG. 4 is an exemplary flow chart of a method of identifying3-dimensional objects in a scene in accordance with an embodiment of theinvention;

FIG. 5 illustrates a screen of a mobile device that is projected onto avirtual surface in accordance with an embodiment of the invention;

FIG. 6 illustrates an interactive three-dimensional video display systemthat includes a wearable monitor in accordance with an embodiment of theinvention; and

FIG. 7 is a schematic illustration of elements of an interactiveprojection system, in accordance with an alternative embodiment of theinvention.

DETAILED DESCRIPTION

In the following description, numerous specific details are set forth inorder to provide a thorough understanding of the various principles ofthe present invention. It will be apparent to one skilled in the art,however, that not all these details are necessarily always needed forpracticing the present invention. In this instance, well-known circuits,control logic, and the details of computer program instructions forconventional algorithms and processes have not been shown in detail inorder not to obscure the general concepts unnecessarily.

As used herein, the term “content projection” may encompassestablishment of an image of the content onto a wearable transparentmonitor, such as see-through eyeglasses, and thus invisible to anyoneother than the person wearing the glasses, or onto a physical objectthat is visible to anyone interacting with the object. The term is notlimited to the above examples. It may encompass forming an image by manymeans, including retinal projection, projection onto see-throughglasses, projection of the image into a virtual space, for example as ahologram, and other techniques for creating augmented reality.

System Architecture.

Turning now to the drawings, reference is initially made to FIG. 1,which is a schematic pictorial illustration of an interactivethree-dimensional video display system 10, which is constructed andoperative in accordance with a disclosed embodiment of the invention.The system 10 incorporates a 3-dimensional (3-D) camera 12, which mayinclude an infra-red (IR) projector and corresponding CMOS/CCD cameraopen for the projector band. The terms “3-dimensional camera” and “3-Dcamera,” as used herein, refer to an imaging device used in forming a3-D map (also referred to as a depth map) of a scene, i.e., an array of3D coordinates, comprising a depth (Z) coordinate value of the bodysurface at each point (X,Y) within a predefined area. The 3-D camera 12captures 3-D information that may includes the body (or at least partsof the body) of the user, tangible entities wielded or operated by theuser for controlling a computer application, and other objects in thefield of view of the 3-D camera 12. Details of a 3-D imaging assembly ofthis sort are described, for example, in PCT International PublicationWO 2010/004542 and U.S. Patent Application Publication No. 2009/0183125,which are herein incorporated by reference. The 3-D camera 12 typicallyoperates in the near infra-red spectrum. However the principles of theinvention are equally applicable to modifications that enable the 3-Dcamera 12 to capture electromagnetic energy outside the near infra-redspectrum, for example far infrared or ultraviolet energy. The system 10may also include a 2-dimensional (2-D) camera 14, which operates in thevisible spectrum, and can acquire a scene with sufficient resolution toallow automatic interpretation of written information in the scene andtypically produces a Red-Green-Blue (RGB) output signal.

The 3-D camera 12 and the 2-D camera 14 are cooperative with a contentprojector 16, all under the control of a processor, such as a computer18.

A suitable unit for use in the system 10 that bundles the 3-D camera 12and the 2-D camera 14 is the PrimeSensor™ Reference Design, availablefrom PrimeSense Corporation, 104 Cambay Ct, Cary N.C., 27513, U.S.A. Thecontent projector 16 may be the PicoP® display engine, available fromMicroVision, Inc., 6222 185th Ave NE Redmond Wash., 98052. In someembodiments, the 3-D camera 12 and the 2-D camera 14 may be integralwith the content projector 16 as a modification of the PrimeSensorReference Design. In one embodiment, the 3-D camera 12 is an integratedmodule that includes an IR projector, which projects a pattern of spotsonto the object and captures an image of the projected pattern.Alternatively, the IR projector, may be embodied as a separate module(not shown). The IR projector may be realized according to the teachingsof U.S. Provisional Applications 61/372,729 (filed Aug. 11, 2010) and61/425,788 (filed Dec. 22, 2010), as well as in PCT InternationalPublication WO 2010/020380, all of which are herein incorporated byreference. These provisional and PCT applications also teach how toreuse the scanning hardware to project both the IR required for depthmapping and the visible content.

The processor may analyze the scene using the teachings of commonlyassigned copending U.S. Patent Application Publication 2011/0293137,entitled “Analysis of Three-Dimensional Scenes”, which is hereinincorporated by reference.

The computer 18 may comprise a general-purpose computer processor, whichis programmed in software to carry out the functions describedhereinbelow. The software may be downloaded to the processor inelectronic form, over a network, for example, or it may alternatively beprovided on non-transitory tangible storage media, such as optical,magnetic, or electronic memory media. Alternatively or additionally,some or all of the image functions may be implemented in dedicatedhardware, such as a custom or semi-custom integrated circuit or aprogrammable digital signal processor (DSP). Although the computer 18 isshown in FIG. 1, by way of example, as a separate unit from the 3-Dcamera 12, some or all of the processing functions of the computer maybe performed by suitable dedicated circuitry associated with or withinthe housing of the 3-D camera 12 and the 2-D camera 14. As will be seenfrom the discussion below, elements of the system 10 may be miniaturizedand incorporated in a wearable monitor to enable the user to move aboutand more freely interact with the scene in near real-time. In any casethe 3-D camera 12 and the 2-D camera 14 function as a sensor component,which observes a scene (users and their surroundings). The computer 18functions as a perception component, which comprehends the scene anduser interaction within these surroundings as mediated or stimulated byinformation provided by the content projector 16.

The computer 18 may execute programs such as Nite™ Middleware, availablefrom PrimeSense, in cooperation with the PrimeSensor Reference Design.For example, the PrimeSensor Reference Design supplies an applicationlayer in the computer 18 with control widgets, thereby providing anapplication programming interface (API) that translates user gestures orpostures into known deterministic application inputs. The Middlewareperforms image processing operations on data generated by the componentsof the system 10, including the 3-D camera 12 with its IR projector, andthe 2-D camera 14 in order to reconstruct 3-dimensional maps of a user20 and acquired scenes. The term “3-dimensional map” refers to a set of3-dimensional coordinates representing the surface of a given object.One form of 3-dimensional map is referred to as a depth image or depthmap, in which each pixel has a value indicating the distance from thecamera to the corresponding point in the scene, rather than thebrightness and color of the point as in a 2-dimensional image. Thecomputer 18 then computes the three-dimensional coordinates of points onthe surface of the control entity by triangulation, based on transverseshifts of the spots in the pattern.

In typical applications, information captured by the 3-D camera 12 isprocessed by the computer 18, which drives the content projector 16. Thecomputer 18 may operate according to a program that is designed tocreate a natural or contrived experience for the user. As shown in FIG.1, the system 10 has recognized a book 22 in the scene, and hasprojected a sale offer 24 onto the book 22: “Buy at $75.99”. The user 20is reacting to the offer by a hand gesture 26, which acts as an input tothe computer 18. Gesture control of a computing device is known, forexample, from commonly assigned U.S. Patent Application Publication No.2009/0183125, which is herein incorporated by reference, and which alsoteaches methods of projection of scenes into a virtual image space.Gesture control is included in the functionality of the Nite™Middleware, which may interpret gestures of the user 20, for example inresponse to the sale offer 24 that are acquired by the 3-D camera 12 andthe 2-D camera 14.

Furthermore, as the interaction of the user 20 with the book 22 and thesale offer 24 evolves, for example, by the user 20 grasping the book 22,a gaze identification module executing in the computer 18 may recognizethat the user 20 is looking at the book 22. By processing the acquired2-D images, the book title may be recognized and interpreted in thesystem 10. Then, computing optimal projection parameters, a book reviewmay be projected onto the book 22. The user 20 could scroll and interactwith the projected book review as if he were viewing it on a displayscreen. In this way, the system 10, cooperatively with the user 20,converts the book 22 in an ad hoc fashion into a virtual informationscreen for the benefit of the user a20.

The system 10 optionally includes a display screen 28 and conventionalinput devices such as a keyboard 30 and mouse 32, which may present auser interface for administrative use, e.g., system configuration, andfor operational control of the system 10 by the user 20.

Reference is now made to FIG. 2, which is a block diagram of the system10 (FIG. 1), in accordance with an embodiment of the invention. A scene34 is acquired concurrently by two cameras, a 2-D camera 36 and a 3-Dcamera 38, which may be separate units or integral as a combined unit.Alternatively, the scene can be captured by the 3-D camera 38 only or bythe 2-D camera 36 only, image analysis performed on the images acquiredin any case. As noted above these cameras may be realized as thePrimeSensor Reference Design. Data output by the 2-D camera 36 and a 3-Dcamera 38 are input to a processor 40, which executes middleware, forexample, the above-mentioned Nite Middleware. The Middleware places thescenes captured by the two cameras in registration. The middlewareincludes an object analysis module 42, which identifies objects in thescene 34 and determines their suitability for content projectionthereon. A projector control module 44, another component of theMiddleware, converts coordinates and characteristics of objects in thescene 34, for example an object 46, and prepares an image forprojection. The module 44 issues suitable instructions for a projector48 such that the image, typically containing information content, isprojected onto the object 46. The instructions may contain correctionsfor distortion attributable to the scale, attitude and configuration ofthe object 46. Additionally or alternatively, the projector 48 mayinclude its own mechanisms to compensate for such distortion.

The position and attitude of the user may be taken into considerationwhen computing projection parameters. For example, as noted above, thegaze vector toward the projected content may vary as the user movesabout in the scene. The projection parameters may be accordinglyadjusted to compensate for such variations, e.g., by adjusting forscale, parallax, and similar distortions, so as to simulate a realisticexperience for the user. One example of such adjustment is a correctionfor the fact that 3-dimensional objects appear differently when viewedfrom different directions, i.e., different sides of the object ordifferent 2-D projections of the object become apparent to the observer.The projection content can be adjusted as a function of the gaze vectorand user position relative to virtual object, thus creating a realisticexperience of the object actually being in the presence of the observer.Gaze direction can be determined by methods known in art. For example,in the case of a device embedded in see-through glasses, head positionorientation is obtainable by rigid registration of the world relative tothe device. Gaze direction can also be measured, for example, usingeye-tracking products available from Tobii Technology, Inc., 510 N,Washington Street, Suite 200, Falls Church, Va. 22046. Gaze may then betranslated into object coordinates using 3D information obtained by thesensor.

Object Awareness.

Techniques for identifying and tracking body parts are known fromcommonly assigned U.S. Patent Application Publication No. 2011/0052006,entitled “Extraction of Skeletons from 3-D Maps”, which is hereinincorporated by reference. Essentially this is accomplished by receivinga temporal sequence of depth maps of a scene containing a humanoid form.A digital processor processes at least one of the depth maps so as tofind a location of a designated body part, such as the head or handestimates dimensions of the humanoid form based on the location. Theprocessor tracks movements of the humanoid form over the sequence usingthe estimated dimensions. These teachings are employed in theabove-mentioned Nite Middleware, and may be enhanced by linking otherknown recognition routines by those skilled in the art.

For example, in the case of identifying the head of the body, theprocessor may segment and analyzes a 3-dimensional form to identifyright and left arms, and then search the space between the arms in orderto find the head. Additionally or alternatively recognition techniquesmay be used. The depth maps may be registered with 2-dimensional imagesof the head or other object. The processor may apply a pattern or facerecognition technique to identify the face of a humanoid form in a2-dimensional image. The face location in the 2-dimensional image isthen correlated with the location of the head of the 3-dimensional form.Using the same techniques, an entire scene may be analyzed, segmented,and known categories of objects identified as candidates for projectionof images thereon.

In one embodiment, which is shown in FIG. 7, upon recognizing the headin an area in which an image is being projected, the processor mayinstruct the projector to reduce the intensity of the light that isprojected in the area of the head (or turn it off entirely) in order toavoid projecting bright light into the eyes, which can be uncomfortableand even hazardous.

Object Processor.

Reference is now made to FIG. 3, which is a block diagram thatschematically shows functional elements of a portion of an exemplaryprocessing device 50, which is a component of the processor 40 (FIG. 2),and which is constructed and operative in accordance with an embodimentof the invention. The processing device 50 may be fabricated as adedicated integrated circuit, on a single semiconductor substrate, witha USB port 52 to an optional host computer 54. Device 50 may includeother interfaces, as well, including an object analyzer 56. The objectanalyzer 56 is linked to a database 58, which holds a library containingdescriptions of objects to be recognized and evaluated by the objectanalyzer 56. It will be appreciated that alternative configurations ofthe processing device 50 can be constructed by those skilled in the art.As noted above, the operations of the processing device 50 may becontrolled by middleware residing in instruction memory 60 and datamemory 62

A depth processor 64 processes the information captured by the 3-Dcamera 12 (FIG. 1) in order to generate a depth map. Depth processor 64uses dedicated memory space in a memory 66. This memory can also beaccessed by a controller 68, which is described hereinbelow, buttypically not by the host computer 54. Rather, depth processor 64 may beprogrammed by the host computer 54 via an application program interface(API).

Depth processor 64 receives input IR data from 3-D camera 12 (FIG. 1)via a depth CMOS interface 70. The depth processor 64 processes thevideo data in order to generate successive depth maps, i.e., frames ofdepth data. The depth processor 64 loads these data into a depthfirst-in-first-out (FIFO) memory 72 in a USB FIFO unit 74.

In parallel with the depth input and processing operations, a colorprocessing block 76 receives input color video data from the 2-D camera14 (FIG. 1) via a color CMOS sensor interface 78. The block 76 convertsthe raw input data into output frames of RGB video data, and loads thesedata into a RGB FIFO memory 80 74 in the unit 74. Alternatively, theblock 76 may output the video data in other formats, such as YUV orBayer mosaic format.

The unit 74 acts as a buffer level between the various data suppliersand a USB controller 82. The unit 74 packs and formats the various datatypes according to different classes (such as a USB video class and aUSB audio class), and also serves to prevent data loss due to USBbandwidth glitches. It arranges the data into USB packets according tothe USB protocol and format prior to transferring them to the USBcontroller.

A high-bandwidth bus, such as an Advanced High-performance Bus (AHB)matrix 84, is used to carry data between the components of theprocessing device 50, and specifically for conveying data from the unit74 to the USB controller 82 for transfer to the host computer 54. (AHBis a bus protocol promulgated by ARM Ltd., of Cambridge, England.) Whenthere are packets ready in the unit 74 and space available in theinternal memory of USB controller 82, the USB controller 82 uses directmemory access (DMA) to read data from memory 72, memory 80, and an audioFIFO memory 86 via an AHB slave module 88 and the matrix 84. The USBcontroller 82 multiplexes the color, depth and audio data into a singledata stream for output via the USB port 52 to the host computer 54.

For the purpose of USB communications, they processing device 50comprises a USB physical layer interface, PHY 90, which may be operatedby the USB controller 82 to communicate via a suitable USB cable with aUSB port of the host computer 54. The timing of the USB PHY iscontrolled by a crystal oscillator 92 and a phase-locked loop 94 (PLL),as is known in the art.

Alternatively, USB controller 86 may optionally communicate with thehost computer via a USB 2.0 Transceiver Macrocell Interface (UTMI) andan external PHY 96.

Various external devices may connect with the processing device 50cooperatively with the host computer 54, including a projector controlmodule 98, which accepts instructions from the processing device 50 andthe host computer 54 to effect a desired image projection onto specifiedcoordinates in space.

The controller 68 is responsible for managing the functions of theprocessing device 50, including boot-up, self-test, configuration, powerand interface management, and parameter adjustment.

The controller 68 may comprise a digital signal processor (DSP) core 100and an AHB master 102 for controlling data movement on the matrix 84.Typically, controller 68 boots from a boot read-only memory 104, andthen loads program code from a flash memory (not shown) via a flashmemory interface 106 into instruction random-access memory 60 and datamemory 62. The controller 68 may, in addition, have a test interface108, such as a Joint Test Action Group (JTAG) interface, for purposes ofdebugging by an external computer 110.

The controller 68 distributes configuration data and parameters to othercomponents of the processing device 50 via a register configurationinterface 112, such as an Advanced Peripheral Bus (APB), to which thecontroller is connected through the matrix 84 and an APB bridge 114.

Further details of the processing device 50 are disclosed in theabove-noted PCT International Publication WO 2010/004542.

Object Analysis.

Continuing to refer to FIG. 3, the object analyzer evaluates datadeveloped by the depth processor 64 in cooperation with the block 76 andthe unit 74 to evaluate a scene captured by the 3-D camera 12 (FIG. 1).

The algorithm executed by the object analyzer 56 may be dictated by anapplication program in the host computer 54. For example, the objectanalyzer 56 may be instructed to search for and report one or more knownobjects in the scene that are specified in the database 58. The hostcomputer 54 may thereupon instruct the content projector 16 (FIG. 1) toproject images on the selected object or objects. Additionally oralternatively, the object analyzer 56 may be instructed to identify andreport objects meeting predefined criteria, without resort to thedatabase 58.

The data communicated by the object analyzer 56 with respect to anidentified object typically includes the size and location of theobject, as well as its orientation, preferably with six degrees offreedom, including scale, pitch, yaw and angular rotation with respectto a reference system of coordinates. This information allows theprojector to compensate for distortions by suitably scaling andcontorting a projected image so as to be project it onto the selectedobject such that the viewer sees an image that is substantiallydistortion-free. Configuration of a projected image is known, e.g., fromU.S. Patent Application Publication No. 20110081072, entitled “ImageProcessing Device, Image Processing Method, and Program”. The image maybe configured in software in order to avoid the expense of complexoptical arrangements and to more easily achieve freedom from sucheffects as off-axis image distortion Alternatively, As noted above,commercially available projects may provide their own compensation fordistortion control.

Reference is now made to FIG. 4, which is an exemplary flow chart of amethod of identifying 3-dimensional objects in a scene in accordancewith an embodiment of the invention. For convenience of presentation,the method is disclosed in conjunction with the apparatus shown in FIG.1 and FIG. 3, but it is applicable to apparatus configured differently.The process steps are shown in a particular linear sequence in FIG. 4for clarity of presentation. However, it will be evident that many ofthem can be performed in parallel, asynchronously, or in differentorders. Those skilled in the art will also appreciate that a processcould alternatively be represented as a number of interrelated states orevents, e.g., in a state diagram. Moreover, not all illustrated processsteps may be required to implement the process. Furthermore, manydetails may vary according to the dictates of the host computer 54 andthe requirements of its application program.

Assume that the viewer is located in a bookshop. At initial step 116 anapplication program executing in the host computer 54 would like toidentify an open book displaying textual information. This is a3-dimensional object having a known definition in the database 58 thatincludes at least one generally light-colored planar surface. The 3-Dcamera 12 is enabled and a 3-dimensional scene captured in theprocessing device 50. The object analyzer 56 evaluates the scene,locates and identifies objects in 3-dimensional space.

At decision step 118 it is determined whether a planar surface has beenlocated in the scene.

Control now proceeds to decision step 120, where it is determined if theplanar surface meets criteria for a book. The criteria may involve,inter alia, size, proximity to certain other objects, and geometricdetails corresponding to a closed or open book.

If the determination at decision step 120 is affirmative, then controlproceeds to final step 122. The coordinates and orientation of the bookare reported by the object analyzer 56 to the controller 68, whichinstructs the projector control module 98 cooperatively with the hostcomputer 54 to display an application-determined image (MENU-1) on theidentified book. The image may contain, for example, options to purchasethe item, or obtain additional details, for example book reviews, andpopularity ratings. Indeed, if the 3-D camera 12 was successful incapturing the title of the book, the additional details may be includedin the projected image. It is assumed that the host computer 54 hasaccess to a local or distributed database or can make automaticinquiries via the Internet.

The coordinates and other characteristics of the book (or of any otherobject onto which an image is to be projected) can also be used incontrolling projection parameters such as the intensity of lightprojected in the image. Thus, for example, the projector may increasethe intensity of the projected light when the object is relatively farfrom the projector and decrease it for nearby objects. Additionally oralternatively, the reflectivity of the object may be assessed (usingimage data from camera 36, for example), and the intensity of theprojected light may be increased when projected onto less reflectiveobjects and decreased for more reflective objects.

If the determination at decision step 120 is negative, then controlproceeds to decision step 124. A determination is made if more objectsare present in the scene for processing.

If the determination at decision step 124 is affirmative, then controlreturns to decision step 118.

If the determination at decision step 124 is negative, then a secondstate of the method commences. It is assumed that the applicationprogram falls through to a secondary option, in which an image isprojected on the user's hand, if visible to the 3-D camera 12.

Control now proceeds to decision step 126, where it is determined if abody part is present in the scene. This may be accomplished using theteachings of the above-noted U.S. Patent Application Publication No.2011/0052006.

If the determination at decision step 126 is affirmative, then controlproceeds to decision step 128, where it is determined if the body partis a hand.

If the determination at decision step 128 is affirmative, then controlproceeds to final step 130, which is similar to final step 122. However,a different menu (MENU-2) is now projected on the hand, which mayinclude, for example, control options for the governing computerapplication. In both final step 122 and final step 130 the image isconfigured so as to create a natural feeling on the part of the userwhen interacting with the content.

Alternatively or additionally, the object analyzer may determine whetherthe body part in question is a head and if so, may instruct theprojector to reduce or turn off the projected intensity in the area ofthe head. This option is described in greater detail hereinbelow withreference to FIG. 7.

If the determination at decision step 128 is negative, then controlproceeds to decision step 132. A determination is made if more objectsare present in the scene for processing.

If the determination at decision step 132 is affirmative, then controlreturns to decision step 126. Otherwise, control passes to final step134, in which a conventional menu display is presented on a displayscreen. Final step 134 represents a failure to identify a suitableexternal object for projection of an image thereon. It will beappreciated that the method shown in FIG. 4 can be varied, andelaborated as required to comply with the specifications of thegoverning application program. Recognition and prioritization of variousobjects and images may be programmed so as to accommodate theconfiguration of a particular scene and the needs of the program itself.

Alternate Embodiment 1

This embodiment is similar to the first embodiment, except a convenientvirtual surface is provided for projection of images and for access bythe user. Reference is now made to FIG. 5, which illustrates a screen136, typically of a mobile information device 138, such as a cellulartelephone, e.g., a “smart phone” that is projected onto a virtualsurface in accordance with an embodiment of the invention. Such devicesare too small for convenient interaction and media consumption. Thescreen 136 incorporates a miniature projector 140 and sensing device142, which have the same functions as the 3-D camera 12 and contentprojector 16 in the embodiment of FIG. 1. Projectors suitable for thispurpose are available, for example, from Microvision. In thisembodiment, the projector 140 projects an image onto a virtualprojection surface 144, which is enlarged relative to the screen 136.

In one mode of operation, the projector 140 may create an enlargedversion of information displayed on the screen 136.

In another mode of operation the sensing device 142 captures an externalscene. The mobile information device 138 is configured to perform themethod of scene analysis described above with reference to FIG. 4. Inthis example, an open book 146 was identified in the external scene. Anapplication program executing in the mobile information device 138 hascaused the projector 140 to project an image 148 of the book 146 ontothe projection surface 144, and to superimpose a menu 150 onto the image148. The menu 150 invites the user to purchase the book 146 at a salesprice of $75.99 or to cancel the display.

Alternate Embodiment 2

In the first embodiment, images have been described as projections ontoa physical object, e.g., a book or a hand. In this embodiment, theprojector may be embodied as a device that projects content onto awearable monitor, such as eye-glasses. In this embodiment final step 122and final step 130 are modified in the method of FIG. 4.

Reference is now made to FIG. 6, which illustrates an interactivethree-dimensional video display system having a wearable monitor inaccordance with an embodiment of the invention. The system is configuredto project the respective images onto the wearable monitor rather thanthe object themselves Such devices offer possibilities of allowing acomputer-generated image produced by the method described with referenceto FIG. 4 to be generated and optionally superimposed on a real-worldview. Such devices may operate by projecting the computer-generatedimage through a partially reflective minor while viewing an externalscene. Alternatively the device may mix the computer-generated image andreal-world view electronically.

In the example of FIG. 6, a user 152 employs a wearable monitor 154,which is capable of displaying stereoscopic imagery. The wearablemonitor 154 is provided with or interfaced with components similar tothose of the system 10 (FIG. 1). Like the system 10, the wearablemonitor 154 is adapted to analyze an external scene. In this example, itidentifies the book 146, and generates an image 156 containing the sameinformation as the image 148 (FIG. 5). The wearable monitor 154 may be aseparate unit or may incorporate other elements of the system 10. In theembodiment of FIG. 6, the wearable monitor 154 includes a miniatureprojector 158 and a sensing element 160. Additionally or alternatively,the wearable monitor 154 may communicate with an external processor orsensing device via a wireless link. Suitable wearable helmet mounteddisplays and see-through eyewear displays for use as the wearablemonitor 154 are available as the Madison line of Novero (novero.com) orfrom Lumus Ltd., 2 Bergman Street Rehovot 76705, Israel.

While the image 156 is actually established within the wearable monitor154, in some embodiments it may be perceived by the user 152 as beingsuperimposed in an external region of space as shown in FIG. 6. Thewearable monitor 154 in such embodiments may be equipped withpositioning, head-tracking and eye-tracking subsystems.

Alternate Embodiment 3

FIG. 7 is a schematic side view of a scanning projector 160 andassociated components in a system for adaptive projection, in accordancewith still another embodiment of the present invention. Projector 160may be used in system 10 (FIG. 1), and offers enhanced capabilities inusing the same scanning hardware to simultaneously project both aninfrared (IR) pattern (for 3-D mapping) and visible content that can beviewed on a screen 162 or other surface. In this sort of embodiment, animage capture device, such as a camera 178 captures an image of theprojected IR pattern, and this image is processed in order to create a3D map of the scene containing screen 162 (which in this examplecontains a person 164). Based on the 3-D map, projector 160 may thenproject onto the scene a visible image that is tailored to the shape andcontours of the objects in the scene, as noted above.

As shown in FIG. 7, a beam combiner 174, such as a dichroic reflector,aligns the IR beam from a radiation source 170 with a visible beam froma visible light source 172. Source 172 may be monochromatic orpolychromatic. For example, source 172 may comprise a suitable laserdiode or LED for monochromatic illumination, or it may comprise multiplelaser diodes or LEDs of different colors (not shown), whose beams aremodulated and combined in order to project the desired color at eachpoint in the field of view. For this latter purpose, combiner 174 maycomprise two or more dichroic elements (not shown) in order to align allof the different colored and IR beams.

A scanning mirror 176 (or a pair of scanning mirrors—not shown) scansthe beams from sources 170 and 172, typically in a raster pattern, overthe field of view of camera 178. While the beams are scanned, projectorcontrol 44 in processor 40 (FIG. 2) modulates sources 170 and 172simultaneously: Source 170 is modulated to generate the desired patternfor 3-D mapping at each point in the field, while source 172 ismodulated according to the pixel value (intensity and possibly color) ofthe visible image that is to be projected at the same point (which maybe based on the 3-D map of the scene at that point). Because the visibleand IR beams are optically aligned and coaxial, the visible image willbe automatically registered with the 3-D map. Alternatively, in place ofcamera 178, projector 160 may also contain another sort of sensingelement, such as an IR detector (not shown), whose field of view isscanned so as to coincide with the projection scan. Such detectionschemes are described, for example, in the above-mentioned PCTInternational Publication WO 2010/020380. Additionally or alternatively,the projector may contain also contain a detector or detectors forvisible light in order to form a color image of the scene.

The projector shown in FIG. 7 is particularly useful in adjusting theprojected image to the characteristics of the scene, since it enablesthe projected pattern to be modified on the fly, pixel by pixel, inperfect registration with the 3-D map that provides the sceneinformation.

As a particular example, when the presence of person 164 is detected inthe scene (by suitably segmenting and analyzing the 3-D map), theintensity of source 172 may be decreased, possibly to the point ofturning off the source altogether, in the area of the person's head orat least in the area of the eyes. In this manner, projector 160 avoidsshining bright light into the person's eyes, which could otherwise causediscomfort and even eye damage.

This principles of this embodiment may be applied using other types ofimaging and projection devices and are not limited to the particularsort of scanning projector and mapping device that are described above.For example, other types of mapping and imaging devices, as well asother image analysis techniques, which may operate on either a 2-D imagecaptured by a suitable capture device or a 3-D map, may be applied inidentifying the area of the eyes for this purpose. Similarly,substantially any suitable type of electronically-driven projector(including standard video projectors) can be controlled in this mannerto reduce intensity in the area of the eyes, as long as an image or mapof the area onto which the projector casts its beam is registered in theframe of reference of the projector. Thus, when the location of the headand/or eyes that is found in the image or map, the corresponding part ofthe projected beam can be dimmed accordingly.

It will be appreciated by persons skilled in the art that the presentinvention is not limited to what has been particularly shown anddescribed hereinabove. Rather, the scope of the present inventionincludes both combinations and sub-combinations of the various featuresdescribed hereinabove, as well as variations and modifications thereofthat are not in the prior art, which would occur to persons skilled inthe art upon reading the foregoing description.

The invention claimed is:
 1. A method for augmented interaction with adata processing system, comprising the steps of: receiving a depth mapof a scene containing 3-dimensional objects meeting first criteria forprojection of images thereon; receiving a 2-dimensional image of thescene; using a digital processor, processing the depth map to locate the3-dimensional objects; executing a computer application to analyze the2-dimensional image to identify a most suitable one of the 3-dimensionalobjects according to second criteria; projecting a user interface to thecomputer application as a content-containing image onto the mostsuitable one of the 3-dimensional objects; using the digital processor,recognizing a gesture; interpreting the gesture as an interaction withthe user interface; and controlling the computer applicationresponsively to the interaction.
 2. The method according to claim 1,wherein processing the depth map comprises identifying a position of themost suitable one of the 3-dimensional objects with six degrees offreedom with respect to a reference system of coordinates, andprojecting a user interface comprises compensating for scale, pitch, yawand angular rotation thereof.
 3. The method according to claim 1,wherein processing the depth map comprises referencing a database of3-dimensional object definitions and comparing the 3-dimensional objectswith the definitions in the database.
 4. The method according to claim1, wherein one of the 3-dimensional objects in the depth map is aportion of a humanoid form.
 5. A method for augmented interaction with adata processing system, comprising the steps of: receiving a depth mapof a scene containing 3-dimensional objects meeting first criteria forprojection of images thereon; using a digital processor, processing thedepth map to locate the 3-dimensional objects; executing a computerapplication to identify a most suitable one of the 3-dimensional objectsaccording to second criteria; projecting an image of the most suitableone of the 3-dimensional objects onto a virtual surface; using thedigital processor, recognizing a gesture; interpreting the gesture as aninteraction with the image of the one object; and controlling thecomputer application responsively to the interaction.
 6. The methodaccording to claim 5, wherein processing the depth map comprisesidentifying a position of the most suitable one of the 3-dimensionalobjects with six degrees of freedom with respect to a reference systemof coordinates, and projecting the image of the one object comprisescompensating for scale, pitch, yaw and angular rotation of the oneobject.
 7. The method according to claim 5, wherein processing the depthmap comprises referencing a database of 3-dimensional object definitionsand comparing the 3-dimensional objects in the depth map with thedefinitions in the database.
 8. The method according to claim 5, whereinthe image of the most suitable one of the 3-dimensional objects furthercomprises a user interface for control of the computer application.
 9. Amethod for augmented interaction with a data processing system,comprising the steps of: receiving a depth map of a scene containing3-dimensional objects meeting first criteria for projection of imagesthereon; using a digital processor, processing the depth map to locatethe 3-dimensional objects; executing a computer application to identifya most suitable one of the 3-dimensional objects according to secondcriteria; projecting an image of the one object onto a wearable monitor;using the digital processor, recognizing a gesture of a user;interpreting the gesture as an interaction with the image of the mostsuitable one of the 3-dimensional objects; and controlling the computerapplication responsively to the interaction.
 10. The method according toclaim 9, wherein processing the depth map comprises identifying aposition of the one object with six degrees of freedom with respect to areference system of coordinates, and projecting the image of the mostsuitable one of the 3-dimensional objects comprises compensating forscale, pitch, yaw and angular rotation of the one object.
 11. The methodaccording to claim 9, wherein processing the depth map comprisesreferencing a database of 3-dimensional object definitions and comparingthe 3-dimensional objects with the definitions in the database.
 12. Themethod according to claim 9, wherein the image of the most suitable oneof the 3-dimensional objects further comprises a user interface forcontrol of the computer application.
 13. An apparatus for processingdata, comprising: a projector, which comprises: a first radiationsource, which emits a beam of infrared radiation; a second radiationsource, which emits a visible light beam, which is modulated to formcontent for projection onto at least a part of a scene; and scanningoptics configured to project both the infrared beam and the visiblelight beam onto the scene simultaneously; a sensing device, which isconfigured to capture the infrared radiation returned from the scene andoutput a signal in response to the captured radiation; and a processor,which is configured to process the signal in order to generate a3-dimensional map of the scene and to process the 3-dimensional map inorder to detect a location of an eye of a person in the scene and tocontrol the projector so as to reduce an intensity of the projectedcontent in an area of the eye.
 14. The apparatus according to claim 13,wherein the first radiation source is controlled to create a pattern ofspots on the scene, and wherein the processor is configured to derive a3-dimensional map of the scene from the pattern of the spots and toprocess the 3-dimensional map in order to identify the area of the eye.15. The apparatus according to claim 13, wherein the sensing device hasa field of view that is scanned so as to coincide with projection of theinfrared beam and the visible light beam onto the scene.
 16. A methodfor processing data, comprising: projecting content onto at least a partof a scene by scanning a visible light beam over the scene, whilemodulating the visible light beam to form the content that is projectedonto at least the part of the scene; scanning a beam of infraredradiation over the scene simultaneously with the visible light beam,capturing the infrared radiation returned from the scene, processing thecaptured radiation to generate a 3-dimensional map of the scene, andprocessing the 3-dimensional map in order to detect a location of an eyeof a person in the scene; and controlling projection of the content soas to reduce an intensity of the projected content in an area of theeye.
 17. The method according to claim 16, wherein scanning the beam ofthe infrared radiation comprises controlling the beam of the infraredradiation to create a pattern of spots on the scene, and whereinprocessing the captured radiation comprises deriving a 3-dimensional mapof the scene from the pattern of the spots, and processing the3-dimensional map in order to identify the area of the eye.
 18. Themethod according to claim 16, wherein capturing the infrared radiationcomprises scanning a field of view of a sensing device, which senses theinfrared radiation, so as to coincide with projection of the infraredbeam and the visible light beam onto the scene.